mRNA extraction from lipid nanoparticles.

Messenger RiboNucleic Acid (mRNA) vaccines have recently shown considerable promises for both prophylactic and therapeutic vaccines. These vaccines do not carry an antigen but the information for producing it using the cell machinery, turning the human body into an antigen factory. However, mRNA is an unstable molecule, susceptible to physical, chemical and enzymatic degradation by exo- and endonucleases. If the mRNA is degraded, it can no longer be translated correctly into the antigen of interest and the vaccine lose its efficacy. To protect from nucleases degradation and allow it to get into the cells, mRNA can be encapsulated in lipid nanoparticles (LNPs). As part of the manufacturing process, the quality of the mRNAs should be controlled before the encapsulation (at the drug substance stage) as well as after formulation on the final vaccine product (at the drug product stage). Therefore, it is necessary to be able to extract the mRNA from the LNPs, that is to deformulate the final vaccine product. In this work, different deformulation methods have been compared: spin column extraction, magnetic particle extraction, organic extraction, and direct disruption. Advantages and disadvantages of each of these methods are highlighted.

Taylor Dispersion Analysis to support lipid-nanoparticle formulations for mRNA vaccines.

Lipid nanoparticles (LNPs) are currently the most advanced non-viral clinically approved messenger ribonucleic acid (mRNA) delivery systems. The ability of a mRNA vaccine to have a therapeutic effect is related to the capacity of LNPs to deliver the nucleic acid intact into cells. The role of LNPs is to protect mRNA, especially from degradation by ribonucleases (RNases) and to allow it to access the cytoplasm of cells where it can be translated into the protein of interest. LNPs enter cells by endocytosis and their size is a critical parameter impacting their cellular internalization. In this work, we studied different formulation process parameters impacting LNPs size. Taylor dispersion analysis (TDA) was used to determine the LNPs size and size distribution and the results were compared with those obtained by Dynamic Light Scattering (DLS). TDA was also used to study both the degradation of mRNA in the presence of RNases and the percentage of mRNA encapsulation within LNPs.

Size and Charge Characterization of Lipid Nanoparticles for mRNA Vaccines.

Messenger RNA vaccines have come into the spotlight as a promising and adaptive alternative to conventional vaccine approaches. The efficacy of mRNA vaccines relies on the ability of mRNA to reach the cytoplasm of cells, where it can be translated into proteins of interest, allowing it to trigger the immune response. However, unprotected mRNA is unstable and susceptible to degradation by exo- and endonucleases, and its negative charges are electrostatically repulsed by the anionic cell membranes. Therefore, mRNA needs a delivery system that protects the nucleic acid from degradation and allows it to enter into the cells. Lipid nanoparticles (LNPs) represent a nonviral leading vector for mRNA delivery. Physicochemical parameters of LNPs, including their size and their charge, directly impact their in vivo behavior and, therefore, their cellular internalization. In this work, Taylor dispersion analysis (TDA) was used as a new methodology for the characterization of the size and polydispersity of LNPs, and capillary electrophoresis (CE) was used for the determination of LNP global charge. The results obtained were compared with those obtained by dynamic light scattering (DLS) and laser Doppler electrophoresis (LDE).

Separation of three strains of polio virus by capillary zone electrophoresis and study of their interaction with aluminum oxyhydroxide.

The development of combination vaccines is essential to reduce the number of injections, shorten vaccination schedules and increase vaccination coverage. Vaccine adjuvants are used to modulate and enhance the immune response induced by the antigens. To support the development of combination vaccines, the study of antigen-adjuvant interactions in the final vaccine formulations is required as interaction competitions may take place between the different antigens. In the present work, a capillary zone electrophoresis (CZE) methodology was firstly optimized on six model proteins, namely bovine serum albumin, ß-lactoglobulin, myoglobin, ribonuclease A, cytochrome C and lysozyme. A cationic dynamic coating (polybrene) and a zwitterionic amino acid additive (ß-alanine) in the background electrolyte were used to reduce the phenomena of protein adsorption on the inner wall of the capillary and thus optimize the separation efficiency of the proteins. The developed methodology was then used to separate three strains from inactivated polio virus, each strain being a whole virus composed of copies of 4 viral proteins and study their interaction with aluminum oxyhydroxide. The antigen-adjuvant interactions could be modulated by addition of phosphate ions playing the role of competitors for the poliovirus.

Antigen-Adjuvant Interactions in Vaccines by Taylor Dispersion Analysis: Size Characterization and Binding Parameters.

Vaccine adjuvants are immunostimulatory substances used to improve and modulate the immune response induced by antigens. A better understanding of the antigen-adjuvant interactions is necessary to develop future effective vaccine. In this study, Taylor dispersion analysis (TDA) was successfully implemented to characterize the interactions between a polymeric adjuvant (poly(acrylic acid), SPA09) and a vaccine antigen in development for the treatment of Staphylococcus aureus. TDA allowed one to rapidly determine both (i) the size of the antigen-adjuvant complexes under physiological conditions and (ii) the percentage of free antigen in the adjuvant/antigen mixture at equilibrium and finally get the interaction parameters (stoichiometry and binding constant). The complex sizes obtained by TDA were compared to the results obtained by transmission electron microscopy, and the binding parameters were compared to results previously obtained by frontal analysis continuous capillary electrophoresis.

Study of Interactions between Antigens and Polymeric Adjuvants in Vaccines by Frontal Analysis Continuous Capillary Electrophoresis.

Vaccine adjuvants are used to enhance the immune response induced by antigens that have insufficient immunostimulatory capabilities. The present work aims at developing a frontal analysis continuous capillary electrophoresis (FACCE) methodology for the study of antigen-adjuvant interactions in vaccine products. After method optimization using three cationic model proteins, namely lysozyme, cytochrome c, and ribonuclease A, FACCE was successfully implemented to quantify the free antigen and thus to determine the interaction parameters (stoichiometry and binding constant) between an anionic polymeric adjuvant (polyacrylic acid, SPA09) and a cationic vaccine antigen in development for the treatment for Staphylococcus aureus. The influence of the ionic strength of the medium on the interactions was investigated. A strong dependence of the binding parameters with the ionic strength was observed. The concentration of the polymeric adjuvant was also found to significantly modify the ionic strength of the formulation, the extent of which could be estimated and corrected.

Development of a Synthetic Substrate for the in vitro Performance Testing of Sunscreens.

PURPOSE: Polymethylmethacrylate (PMMA) plates generally used for the in vitro testing of sunscreens have failed to yield a satisfactory correlation between the sun protection factor (SPF) in vitro and that in vivo. In the present study, various polymers were investigated as alternative substrates to PMMA plates. PROCEDURES: In total, 14 polymers were tested in terms of ultraviolet (UV) transparency by transmission spectroscopy, and surface properties by contact angle measurement. The polymers that were UV transparent and that showed surface properties similar to human skin were mold-injected in casts with various degrees of roughness to obtain corresponding substrate plates. To assess them, the in vitro SPF of 1 sunscreen was measured on a mold-injected PMMA plate as well as on the proposed polymer plates and compared to the in vivo SPF. RESULTS: Four polymers showed a UV transmittance at 310 nm of more than 50%, as well as a total surface free energy close to the reported value for human skin. Of these, 2 provided an in vitro SPF matching the in vivo SPF contrary to the mold-injected PMMA plate for the tested oil-in-water sunscreen. CONCLUSION: This work demonstrates the possibilities of using alternative polymers for synthetic substrates for in vitro sunscreen testing.